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Acta Agron Sin ›› 2009, Vol. 35 ›› Issue (4): 718-723.doi: 10.3724/SP.J.1006.2009.00718

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Effect of Potassium Deficiency on Root Growth of Cotton(Gossipium hirsutum L.)Seedlings and Its Physiological Mechanisms Involved

ZHANG Zhi-Yong12,WANG Qing-Lian1,LI Zhao-Hu1,DUAN Liu-Sheng1,TIAN Xiao-Li1*   

  1. 1Agronomy and Biotechnology College/State Key Laboratory of National Plant Physiology and Biochemistry,China Agricultural University,Beijing 100193,China;2School of Life Science and Technlogy,Henan Institute of Science and Technology,Xinxiang 45003,China
  • Received:2008-08-29 Revised:2008-12-13 Online:2009-04-12 Published:2009-02-16
  • Contact: TIAN Xiao-Li E-mail:tian_xiaoli@163.com E-mail:tian_xiaoli@163.com

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Abstract:

Premature senescence caused by potassium (K) deficiency has been an important limiting factor in cotton production in China, and K uptake ability of plant from media has a close correlation with root growth and development. In the present study, cotton cultivar NuCOTN99B was sowed in sand in growth chamber, uniform cotton seedlings were transferred to 1/2-strength modified Hoagland’s solution with low (0.05 mmol L-1) or moderate (0.50 mmol L-1) K+ at 4 d after germination to investigate the effect of K levels on the root system indicators, endogenous free indole acetic acid (IAA) content and ethylene amount released from the cotton seedlings root. The results showed that the lateral root formation of seedlings grown in low K solution for four days was significantly inhibited by about 20%. After 10 d treatment, root elongation was also significantly reduced. Furthermore, we found that the reduction of lateral root was mainly resulted from short length of branched root zone, and there was no change in the density of lateral root under lower K. In addition, root system was classified into fine roots (0.05–0.20 mm), middle roots (0.25–0.45 mm), and coarse roots (> 0.45 mm) according to root diameter. Total root length and total root surface area of cotton seedlings grown in low K media for four days reduced by about 60%, and the fine root was inhibited severely, the coarse roots moderately, and the middle roots slightly. For example, the root length, root surface area and root volume of fine roots grown in low-K media for 4 and 10 d were only approximately 10% and 25% of those in moderate-K media, respectively. Additionally, only fine roots were constantly inhibited by low-K during treatment period in terms of the ratios of different diameter’s roots to total roots, which resulted in the fact that the magnitude of K deficiency in cotton seedling was higher than that of inhibition of root growth, because the uptake activity in fine roots is higher than those in middle and coarse roots. For example, the accumulated K of seedlings grown in low-K solution for 4 d and 10 d were 25% and 16% of that grown in moderate-K solution, respectively; whereas the total root length and total root surface area were 35.7–38.0% (4 d) and 47.7–50.6% (10 d). As expected, the endogenous free indole acetic acid (IAA) content in roots grown in low-K media was reduced by 50%, whereas the amount of ethylene release had nearly six-fold increase, which might provide an explanation to some extent for the inhibition of lateral root formation and root elongation by potassium deficiency.

Key words: Cotton(Gossipium hirsutum L.), Potassium(K), Root growth, Indole acetic acid(IAA), Ethylene

[1] Marschner H. Mineral Nutrition of Higher Plants. London: Academic Press. 1995
[2] Pettigrew W T, Meredith Jr W R. Dry matter production, nutrient uptake, and growth of cotton as affected by potassium fertilization. J Plant Nutr, 1997, 20: 531–548
[3] Zhou T-H(周桃华), Zhang H-P(张海鹏), Liu L(刘玲). Studies on effect of potassium fertilizer applied on yield of Bt cotton. Chin Agric Sci Bull (中国农学通报), 2006, 22(8): 292–296 (in Chinese with English abstract)
[4] Zhang Z Y, Tian X L, Duan L S, Wang B M, He Z P, Li Z H. Differential responses of conventional and Bt-transgenic cotton to potassium deficiency. J Plant Nutr, 2007, 30: 659–670
[5] Drew M C. Comparison of the effects of a localized supply of phosphate, nitrate, ammonium, and potassium on the growth of the seminal root system and the shoot in barley. New Phytol, 1975, 75: 479–490
[6] Chen J-X(陈际型). Effect of K nutrition on rice root growth and nutrient uptake. Acta Pedolog Sin (土壤学报), 1997, 34(2): 182–188(in Chinese with English abstract)
[7] Shin R, Schachtman D P. Hydrogen peroxide mediates plant root cell response to nutrient deprivation. Proc Natl Acad Sci USA, 2004, 101: 8827–8832
[8] Armengaud P, Breitling R, Amtmann A. The potassium-dependent transcriptome of Arabidopsis reveals a prominent role of jasmonic acid in nutrient signalling. Plant Physiol, 2004, 136: 2556–2576
[9] Rengel A, Damon P M. Crops and genotypes differ in efficiency of potassium uptake and use. Physiol Plant, 2008, 133: 624–636
[10] Gerik T J, Morrison J E, Chichester F W. Effects of controlled-traffic on soil physical properties and crop rooting. Agron J, 1987, 79: 434–438
[11] Cope J T. Effects of 50 years of fertilization with phosphorus and potassium on soil test levels and yields at six locations. Soil Sci, 1981, 45: 342–347
[12] Mengel K. Response of various crop species and cultivars to fertilizer application. Plant Soil, 1983, 72: 305–319
[13] Brouder S M, Cassman K G. Root development of two cotton cultivars in relation to potassium uptake and plant growth in a vermiculitic soil. Field Crops Res, 1990, 23: 187–203
[14] Tian X-L(田晓莉), Wang G-W(王刚卫), Zhu R(朱睿), Yang P-Z(杨培珠), Duan L-S(段留生), Li Z-H(李召虎). Conditions and indicators for screening cotton (Gossypium hirsutum) genotypes tolerant to low-potassium. Acta Agron Sin (作物学报), 2008, 34(8): 1435–1443 (in Chinese with English abstract)
[15] Jing C-C(姜存仓), Wang Y-H(王运华), Lu J-W(鲁剑巍), Xu F-S(徐芳森), Gao X-Z(高祥照). Advances of study on the K-efficiency in different plant genotypes. J Huazhong Agric Univ (华中农业大学学报), 2004, 23(4): 483–487 (in Chinese with English abstract)
[16] Cassman K G, Kerby T A, Roberts B A, Bryant D C, Brouder S M. Differential response of two cotton cultivars to fertilizer and soil potassium. Agron J, 1989, 81: 870–876
[17] Kang H M, Saltveit M E. Reduced chilling tolerance in elongating cucumber seedling radicals is related to their reduced antioxidant enzyme and DPPH-radical scavenging activity. Physiol Plant, 2002, 115: 244–250
[18] Edlund A, Eklǒf S, Sundberg B, Moritz T, Sandberg G. A microscale for gas chromatograph-mass spectrometry measurements of picogram amounts of indole-3-acetic in plant tissues. Plant Physiol, 1995, 108: 1043–1047
[19] Reddy K R, Zhao D L. Interactive effects of elevated CO2 and potassium deficiency on photosynthesis, growth, and biomass partitioning of cotton. Field Crops Res, 2005, 94: 201–213
[20] Gopal R, Dube B K, Sinha P, Chatterjee C. Potassium stress changes in cotton metabolism. Annu Agric Res, 2001, 22: 253–257
[21] Pettiet J V. Calibration of the Mehlich 3 soil test for potassium using leaf analyses and potassium deficiency symptoms in cotton plants. Commun Soil Sci Plant Anal, 1994, 25: 3115–3127
[22] Singh D, Brar M S, Brar A S. Critical concentration of potassium in cotton (Gossypium hirsutum L.). J Agric Sci, 1992, 118: 71–75
[23] Graham R D. Breeding for nutritional characteristic in cereals. Adv Plant Nutr, 1984, 1: 57–102
[24] Sullivan W M, Jiang Z C, Hull R J. Root morphology and its relationship with nitrate uptake in Kentucky bluegrass. Crop Sci, 2000, 40: 765–772
[25] Zhang H, Forde B G. An Arabidopsis MADS box gene that controls nutrient-induced changes in root architecture. Science, 1998, 279: 407–409
[26] Kutz A, Muller A, Henning P, Kaiser W M, Piotrowsky M, Weiler E W. A role for nitrilase in the regulation of root morphology in sulphur-starving Arabidopsis thaliana. Plant J, 2002, 30: 95–106
[27] Linkohr B I, Williamson L C, Fitter A H, Leyser O. Nitrate and phosphate availability and distribution have different effects on root system architecture of Arabidopsis. Plant J, 2002, 29: 751–760
[28] López-Bucio J, Cruz-Ramírez A, Herrera-Estrella L. The role of nutrient availability in regulating root architecture. Curr Opin Plant Biol, 2003, 6: 280–287
[29] Hodge A. The plastic plant: Root responses to heterogeneous supplies of nutrients. New Phytol, 2004, 162: 9–24
[30] de Jager A. Effects of localized supply of H2PO4-, NO3-, SO42-, Ca2+ and K+ on the production and distribution of dry matter in young maize plants. Neth J Agric Sci, 1982, 30: 193–203
[31] Scott B J, Robson A D. The distribution of Mg, P and K in the split roots of subterranean clover. Ann Bot, 1991, 67: 251–256
[32] Sánchez-Calderón L, López-Bucio J, Chacón-López A, Cruz-Ramírez A, Nieto-Jacobo B, Dubrovsky J G, Herrera-Estrella L. Phosphate starvation induces a determinate developmental program in the roots of Arabidopsis thaliana. Plant Cell Physiol, 2005, 46: 174–184
[33] Bednarz C W, Oosterhuis D M, Evans R D. Leaf photosynthesis and carbon isotope discrimination of cotton in response to potassium deficiency. Environ Exp Bot, 1998, 39: 131–139
[34] Zhao D, Oosterhuis D M, Bednarz C W, Influence of potassium deficiency on photosynthesis, chlorophyll content, and chloroplast ultrastracture of cotton plants. Photosynthetica, 2001, 39: 103–109
[35] Pettigrew W T. Potassium deficiency increases specific leaf weights and leaf glucose levels in field-grown cotton. Agron J, 1999, 91: 962–968
[36] Casimiro I, Beeckman T, Graham N, Bhalerao R, Zhang H, Casero P, Sandberg G, Bennett M J. Dissecting Arabidopsis lateral root development. Trends Plant Sci, 2003, 8: 165–171
[37] Bates T R, Lynch J P. Stimulation of root hair elongation in Arabidopsis thaliana by low phosphorus availability. Plant Cell Environ, 1996, 19: 529–538
[38] Zhang H M, Jennings A, Barlow P W, Forde B G. Dual pathways for regulation of root branching by nitrate. Proc Natl Acad Sci USA, 1999, 96: 6529–6534
[39] Linkohr B I, Williamson L C, Fitter A H, Leyser H M O. Nitrate and phosphate availability and distribution have different effects on root system architecture of Arabidopsis. Plant J, 2002, 29: 751–760
[40] Ashley M K, Grant M, Grabov A. Plant responses to potassium deficiency: a role for potassium transport proteins. J Exp Bot, 2006, 57: 425–436
[41] Vicente-Agullo F, Rigas S, Desbrosses G, Dolan L, Hatzopoulos P, Grabov A. Potassium carrier TRH1 is required for auxin transport in Arabidopsis roots. Plant J, 2004, 40: 523–535
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